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Implementing 2.5D and 3D Devices Bob Patti, CTO rpatti@tezzaron.com

Implementing 2.5D and 3D Devices Bob Patti, CTO rpatti@tezzaron.com. The Effect of 2.5/3D on Devices. Span of 3D Integration. 1s/ sqmm Peripheral I/O Flash, DRAM CMOS Sensors. Packaging. Wafer Fab. CMOS 3D. CMOS 3D. Analog. Analog. Flash. Flash. Tezzaron 3D-ICs

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Implementing 2.5D and 3D Devices Bob Patti, CTO rpatti@tezzaron.com

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  1. Implementing 2.5D and 3D Devices Bob Patti, CTO rpatti@tezzaron.com

  2. The Effect of 2.5/3D on Devices

  3. Span of 3D Integration 1s/sqmm Peripheral I/O • Flash, DRAM • CMOS Sensors Packaging Wafer Fab CMOS 3D CMOS 3D Analog Analog Flash Flash Tezzaron 3D-ICs 100-1,000,000/sqmm 1000-10M Interconnects/device DRAM DRAM DRAM DRAM CPU CPU 3D Through Via Chip Stack IBM/Samsung IBM • 100,000,000s/sqmm • Transistor to Transistor • Ultimate goal

  4. TSV Pitch ≠ Area ÷ Number of TSVs 1024 bit bus Single layer interconnect 10um TSV 20um Pitch 1um TSV 2um Pitch FPU • TSV pitch issue example • 1024 bit busses require a lot of space with larger TSVs • They connect to the heart and most dense area of processing elements • The 45nm bus pitch is ~100nm; TSV pitch is >100x greater • The big TSV pitch means TOF errors and at least 3 repeater stages

  5. 3D Interconnect Characteristics Small fine grain TSVs are fundamental to 3D enablement

  6. 3rd Si thinned to 5.5um 2nd Sithinned to 5.5um SiO2 1st Si bottom supporting wafer

  7. Honeywell 0.6um SOI TSV 120K TSVs

  8. RF, Imaging, Processing, Analog

  9. “Dis-Integrated” 3D Memory Memory Layers from DRAM fab Memory Cells Controller Layer from high speed logic fab Wordline Drivers BiSTAR Senseamps I/O Drivers Power,Ground, VBB,VDH Wordlines Bitlines 2 million vertical connections per lay per die

  10. Gen4 “Dis-Integrated” 3D Memory DRAM layers 42nm node 2 million vertical connections per lay per die Controller layer contains: senseamps, CAMs, row/column decodes and test engines. 40nm node I/O layer contains: I/O, interface logic and R&R control CPU. 65nm node Better yielding than 2D equivalent!

  11. Novati Heritage SEMATECH Austin site opens for business SEMATECH spins off the R&D wafer fab and associated labs as Advanced Technology Development Facility (ATDF) Tezzaron Semiconductor acquires the former SVTC facility. 2013 1987 1988 1995 2004 2007 2012 14 U.S.-based semiconductor manufacturers & U.S. government form consortium, called SEMATECH The International 300 mm Initiative (I300I) was formed as a subsidiary of SEMATECH. ATDF merges with former Cypress Semiconductor facility, SVTC Technologies.

  12. Tezzaron/Novati 3D Technologies • “Volume” 2.5D and 3D Manufacturing in 2013 • Interposers • Future interposers with • High K Caps • Photonics • Passives • Power transistors • Wholly owned Tezzaron subsidiary • Cu-Cu, DBI®, Oxide, IM 3D assembly

  13. Facility Overview • Capabilities • Over 150 production grade tools • 68000 sq ft Class 10 clean room • 24/7 operations & maintenance • Manufacturing Execution Systems (MES) • IP secure environments, robust quality systems • ITAR registered • Full-flow 200mm silicon processing, 300mm back-end (Copper/Low-k) • Process library with > 25000 recipes • Novel materials (ALD, PZT, III-V, CNT, etc) • Copper & Aluminum BEOL • Contact through 193nm lithography • Silicon, SOI and Transparent MEMS substrates • Electrical Characterization and Bench Test Lab • Onsite analytical tools and labs: SIMS, SEM, TEM, Auger, VPD, ICP-MS, etc • ISO 9001:2008 13485:2013 • TRUST 2013

  14. 2.5/3D in Combination IME A-Star / Tezzaron Collaboration IME A-Star / Tezzaron Collaboration

  15. Tezzaron Dummy Chip C2C Assembly Memory die C2C sample X-section of good micro bump CSCAN showed no underfill voids (UF: Namics 8443-14) X-ray inspection indicated no significant solder voids

  16. Near End-of-Line TSV Insertion M8 TM 2x,4x,8x Wiring level ~.2/.2um S/W M5 M4 W M5 M7 M6 M4 M3 M1 M2 SIN poly TSV is 1.2µ Wide and ~10µ deep STI 5.6µ

  17. Advanced Photonic Interposers • 2pJ/bit power target • WDM • Multicore fiber • 25Gb channel interface • Self-calibrating self-tuning

  18. Double Sided Silicon Interposer

  19. Integrating Fluidics into 3D: Liquid Cooling

  20. 3D Key to Enable Next Gen 16nm Sea-of-Gates 14nm Sea-of-SRAM 65nm Analog and I/O IP isolation Optimized Process Simplified Technology Real Reuse

  21. 2.5/3D Design Enablement • Complete 3D PDK 8th Release • GF 130nm • Synopsys, Hspice, Cadence, MicroMagic 3D physical editor • Calibre 3D DRC/LVS • Artisan standard cell libraries • MOSIS, CMP, and CMC MPW support • 130nm, coming soon 65nm • Silicon Workbench • Honeywell 150nm SOI • NEOL TSV insertion • 40→28nm 3D logic • Silicon interposers, active, photonics • eSilicon 2.5/3D solutions, organic interposers • >100 devices in process • >500 users

  22. Summary • “One stop” 2.5/3D solution provider • Open technology platform • Volume 2.5D Si interposer production • Volume 3D assembly • High performance, ULP, extreme density memories • TSV Insertion • Silicon, 3/5 materials, carbon nanotubes • “Fully Engineered” Sensors Computing MEMS Communications

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